NL1043845B1 - A row type heat pipe temperature conducting device - Google Patents

Abstract

The utility model relates to a row type heat pipe temperature conducting device, comprising: double-pipe heat exchangers including the upper and lower double-pipe heat exchanger, wherein connecting parts (used for connecting pipelines for conveying a temperature transmitting medium) are arranged at the two ends of the double-pipe heat exchangers; Row type heat pipes connected with the upper and the lower double-pipe heat exchanger, wherein the row type heat pipes comprise multiple heat pipes arranged in the axial directions of the double-pipe heat exchangers at intervals, and the two ends of each heat pipe make contact with the upper and the lower double-pipe heat exchanger correspondingly; the temperature transmitting medium conducts the temperature to the row type heat pipes through the double-pipe heat exchangers, then temperature is diffused to the exterior; the temperature conducting device is light in weight, long in service life, safe, stable and good in heat conduction rate.

Description

A row type hear pipe temperature conducting devices Technical field The utility model relates Lo the technical field of temperature conducting devices, in particular to a row type heat pipe temperature conducting device.

Background technology Heating plates on the market usually refer to water heating, namely, circulating walter is heated through a wall-hurg stove or a boiler, Then, the circulating water is connected to the heating plates through pipelines, and the proper temperature is ultimately output through the heating plates, causing a difference in the indoor temperature.

Thus, through the heat circulation that is carried out, the whole indoor temperature will rise evenly.

In the case of air heating, water is treated through water treatment equipment and heated in heating equipment (boiler), evaporating the water.

The heat is supplied to rooms by evaporating water through the heating plates.

The hot water is obtained through the gas wall-hung furnace, and the steam produced from the hot water is conveyed into the indoor heating plates through pipelines.

After the heat has dissipated, the indoor 28 temperature will evenly rise, and finally heat circulation is carried out, and therefore household heating is achieved.

The heat dissipation process is: the heat of the hot water in the heating plates is transmitted to the inner walls of the heating plates through convection heat exchange, and then the heat is transmitted fo the outer walls by the inner walls through heat conduction.

Most heat is transmitted to air by the outer wails through convection heat exchange, and a small part of heat is transmitted to people through radiation.

However, in the case of various metal sheets made of traditional materials, due to the materials and structures of the heating plates, the inner walls of the heating plates are not smooth, the flow rate is affected, impurities easily adhers to the inner walls, and water scale is easily formed.

Furthermore, the heating plates are weak to chemical corrosion of salt. acid and alkali, the effect becomes worse and worse after long-time use, and blockages, leakage, surface paint peeling rust and other phenomena are easily caused.

Therefore, whenever winter comes, water needs to be supplied and the heating has to be tested, as people worry about leakage caused by corrosion, as well as other problems of the heating plates.

The requirements for the water guality are high, as the heating plates are easily corroded and are easily oxidized to rust, affecting its service life.

Thus, temperature conducting equipment which is low in cost, environmentally friendly and resistant to corrosion is uggently needed to meet the daily reguirements of people. Content of utility model A The utility model provides the temperature conducting device which is low in weight, long in service life, safe and stable, and has a good heat conduction rate, in order to overcome the defects in the prior art.

In order to achieve its purpose, the utility model is realized through the following technical scheme: a row type heat pipe temperature conducting device, comprising: doubls- pipe heat exchangers including the upper double-pipe heat exchanger and the lower double-pipe heat exchanger, wherein connecting paris are arranged at the two ends of the double-pipe heat exchangers, and the connecting parts are used for connecting pipelines for conveying a temperature transmitting medium; Row type heat pipes connected with the upper double-pipe heat exchanger and the lower double-pipe heat exchanger, whersin ths row type heat pipes comprise multiple heat pipes arranged in the axial directions of ths double~ pipe heat exchangers at letervals, and the two ends of each heat pipe make contact with the upper double-pipe heat exchanger and the lower double-pipe heat axchanger correspondingly; the temperature transmitting medium conducts the temperature te the row type heat pipes through the double-pipe heat exchangers, and then the temperature is diffused to the exterior.

Preferably, the doublerpipe heat exchangers are tubular heat pipes, passageways Tor conveying the Lemperature transmitting medium are formed in the pipes, the double-pipe heat exchangers are directly manufactured from heal. pipes, cold and heat sources of the temperature transmitting medium can be directly absorbed, and therefors the heat conduction efficiency is further improved.

Preferably, each double~pipe heat exchanger comprises an inner pipe and an outer pipe, wherein the iner pipe and the outer pipe are concentrically arranged. The outer pipe is a tubular healt pipe, the inner pipe is coated with the outer pipe. The outer wall of the inner pipe is tightly attached to the inner wall of the outer pipe. The inner pipe is completely coated 3& with the tubular heat pipe of the outer pipe, the temperature conducted by the inner pipe can be directly absorbed by the heat pipe, and the heat conduction efficiency is improved.

Preferably, the row type heat pipes penetrate through the inner walls of the double-pipe heat exchangers and then stretch into the double-pipe 40 heat exchangers, so that the temperature transmitting medium entering the double~pipe heat exchangers directly makes contact with one ends of the heat pipes, The beat pipes directly make contact with the temperature transmitting medium, the cold and heat sources can be rapidly conducted fo the other ends of the heat pipes, thus, the temperature is rapidly conducted into air, and the heat conduction efficiency is improved.

Preferably, the heat pipes in the row type heat pipes are flat heat pipes and connected with the flat positions of one side of the outer walls of the double~pipe heat exchangers in an attached manner. Low-temperature tin smoldering or other physical methods can be adopted for fastening in attached connection. The flat heat pipes make contact with the flat positions of the double-pipe heat exchangers in order to increase the contact area during conduction, the heal conduction efficiency can be improved, and meanwhile under the condition that the outer surfaces of the double-pipe heat exchangers are not damaged, the leakage problem of the temperature transmitting medium is effectively avoided.

Preferably, a phase change working medium is injected into the vacuumized heat pipes in a sealed manner, and grooves or capillary cores are arranged in the heat pipes.

Prefersbly, multiple pairs of heat dissipating fins vertical to the row Lype heat pipes are arranged belween the row type heat pipes, the multiple pairs of heat dissipating fins are arranged in the direction vertical Lo the row type heat pipes, the diffusion area of temperature sources can be effectively increased through the heat dissipating fins, and therefore the temperature sources are evenly and rapidly diffused to the exterior.

Preferably, the heat dissipating fins are transversely provided with multiple positioning holes. The heat pipes penetrate through the positioning holes. The outer walls of the heat pipes make contact with the heat digsipating fins at the Joints of the positioning holes. The heat dissipating fins can achieve certain supporting and fixing effects on the heat pipes through the positioning holes formed in the heat dissipating fins, meanwhile, ithe heal dissipating fins achieve a certain protection effect, and therefore the heat pipes are prevented from being damaged and broken by external force.

Preferably, the two ands of the double-pipe heat exchangers are connected through supports. Fixing holes are formed in the upper and lowsr faces of the supports, and the two ends of the double-pipe heat exchangers pesnelcalLe through the fixing holes to be fixed.

Preferably, a circle of housing 1s arranged on the outer sides of the double-pipe heat exchangers and the row type heat pipes. The housing is 40 fixed through supports on the two sides. The housing is reticular. The housing achieves a protection effect on ithe heat pipes and also prevents the human body or other animals from being scalded as the human body or other animals directly suffer from high temperature at the positions of the heat pipes, and meanwhile temperature sources can be dissipated through the â reticular structure.

Compared with the prior art, in the utility model, the heat pipes are adopted for replacing conventional heating plates to be used as a heat transfer medium, and the heat pipes have performance features: 1. All the cold and heat sources can be applied, and the application range is wide. 2.

0 Light weight: As the main heat Lransfer medium, the heat pipes are Light in weight, it is not needed to feed the temperature transmiiting medium to the interiors again, and therefore the overall weight is light. 3. Supersonic heat transfer: The heat pipes are driven heat transfer elements with sxtremely high heat conducting performance, and by means of the phase change 18 principle and the capillary effect, the heat transfer efficiency of the heat pipes is hundreds of times to thousands of times higher than that of purs copper made of the same material. 4. Operation without water: The heat pipes are integrally formed, the interiors are under operation without water, thus, the phenomena of emitting, dripping and leaking of traditional water heating are avoided, and the heal pipes are convenient: to install, free of maintenance and long in service life. 5. Convenient installation: The structure is simple, and installation and construction can be carried out without professional personnel.

Description with figures Figure 1 is the overall structure diagram of this vtility model; Figure 2 is the internal structure diagram of the utility model after the housing is removed; Figure 3 is the vertical view of the utility model and the section view in four directions: Figure 4 is the support structure diagram of the utility model, In the drawings: 1. Double-pipe healt exchanger, 2. Row type heat pipe, 3. Connecting part, 4. Heat dissipating fin, 5. Housing, 6. Support, 11.

Outer pipe, 12. Inner pipe, Detailed Description of thes Preferred Embodiments Combining the attached figure, there is a clear and complete description of the technical schemes in embodiments of this utility model. Obviousiy, 40 only some embodiment of this invention (instead of all the utility model cases) are described here. Based on the embodiment for the utility model, all cther embodiments acquired by the ordinary technicians in this field without creative endeavors, shall be in the protection scope of the utility modal.

5 As shown in Figures l and 2, this embodiment discloses a row type heat pipe 2 temperature conducting device, comprising: double-pipe heat exchangers including the upper doubls-pipe heat ezchangerl and the lower double-pipe heat exchangerl, wherein connecting parts 3 are arranged at the two ends of the double-pipe heat exchangers, and the connecting parts are used for connecting pipelines for conveying a temperature transmitting medium; Row type heat pipes 2 connected with the upper doeuble-pipe heat exchanger 1 and the lower doubie-pipe heat exchanger 1, whersin the zow type heat pipes 2 comprise multiple heat pipes arranged in the axial directions of the double-pips heat exchangers 1 at intervals, and the two ends of each heat pipe make contact with the upper double-pipe heal exchanger Ll and the Lower double-pipe heat exchanger 1 correspondingly; and the temperature transmitting medium conducts the temperature to the row type heat pipes 2 through the double-pipe heat exchangers 1, and then the temperature is diffused to the exterior; The row type heat pipe 2 temperature conducting device can achieve refrigerating and heating functions according to different fed temperaturs transmitting medium such as different cold sources or heat sources, The cold sources or the heat sources can be various kinds of gas or liquid or 23 generated by refrigerating and heating devices. The upper double-pipe heat exchanger 1 is mainly used for conveying the cold sources, the lower dotble~ pipe heat exchanger is used for conveying the heat sources, or the same zide ends of the upper double-pipe heat exchanger 1 and the lower double- pipe heat exchanger 1 are conducted, thus, the temperature transmitting medium comes in from the other side of the upper double-pipe heat exchanger àl and goes out from one side of the lower double-pipe heat exchanger 1, then simultaneous temperature conduction of the two ends for the row type heat pipes 1 in the middle is formed, and the heat conduction efficiency is further enhanced.

Each double~pipe heat exchanger 1 comprises an inner pipe 12 and an outer pipe 11, wherein the inner pipe 12 and the outer pipe 11 are concentrically arranged. The outer pipe 11 is a tubular heat pipe, the inner pipe 12 is coated with the outer pipe 11. The outer wall of the inner pips 12 is tightly attached to the inner wall of the outer pipe 11, the inner 40 pipe 12 is completely coated with the tubular heat pipe of the outer pipe

11. The temperature conducted by the inner pipe 12 can be direcLiy absorbed by the heat pipe, and the heat conduction efficiency is improved; and preferably, the inner pipes 12 ars not arranged in the double-pipe heat exchangers 1, the tubular heat pipes are directly arranged in the double- pipe heat exchangers, passageways for conveying the temperature transmitting medium are formed in the pipes, thus, the heat pipes directly make contact with the temperature transmitting medium, asd cold and heat sources can be rapidly conducted to the other ends of the heat pipes, thus, the temperature is rapidly conducted into air, and the heat conduction efficiency is higher.

As shown in Figure 3, the row type heat pipss 2 are inserted into the double-pipe heat exchangers 1, the temperature transmitting medium entering the double-pips heat exchanger 1 directly makes contact with one ends of the heat pipes.

The heat pipes directly make contact with the temperature transmitting medium, the cold and heat sources can be rapidly conducted to the other ends of the beat pipes, thus, the temperature is rapidly conducted to the exterior, and the heat conduction efficiency is improved; and meanwhile, the heat pipes in the row type heat pipes 2 can be flat heat pipes, the heat pipes are connected with the flat positions of one sides of the outer walls of the double-pipe heat exchangers 1 in an attached manner, the flat heat pipes make contact with the flat positions of the double-pipe heat exchangers 1, thus, the contact area during conduction is increased, the conduction efficiency can be improved, and meanwhile under the condition that the outer surfaces of the double-pipe heat exchangers 1 are not damaged, the leakage preblem of the temperature transmitting medium is effectively avoided,

The heat pipes are driven heat transfer elements with extremely high heat conducting performance, and by means of the phase change principle and the capillary effect, the heat transfer efficiency of the heat pipes is hundreds of times to thousands of times higher than that of pure copper made of the same material.

A phase change medium is injected into the vacoamized heal! pipes in a sealed manner, liquid absorbing core structures are arranged on the walls of the heat pipes, and hy depending on capillary force generated by liquid absorbing cores, condensed liguld returns to the evaporation end from the condensation end.

After the interiors of the heat pipes are vacuumized, liquid is injected befors sealing again.

The pressure in the heat pipes is determined by the pressure of steam obtained after working liquid evaporates.

As long as the surfaces of the heat pipes are heated, the working liquid evaporates.

The temperature and the pressure of the steam at the evaporation end are slightly higher than the temperature

43 of other portions of the heat pipes, thus, the pressure difference is generated in the heat pipes, the steam is promoted to flow to the cold ends in the heat pipes, when the steam is condensed on the walls of the heat pipes, latent heat of vaporization of the steam is released, thus, heat is transferred to the condensation end, and then the condensed liquid returns to the evaporation end again through the liguid absorbing core structures of the heat pipes.

Thus, as long as heat source body heating exists, this process will be cyclically carried out, and the heat pipes are round or flat heat pipes.

As: shown in Figures 2 and 3, multiple pairs of heat dissipating fins 4 18 vertical to the row type heat pipes 2 are arranged between the row type heat pipes, the multiple pairs of heat dissipating fins 4 are arranged in the direction vertical to the row type heat pipes 2, the diffusion area of temperature sources can be effectively increased through the heat dissipating fins, and therefore the Ctemperatvre sources are evenly and rapidly diffused to the exterior, The heat pipes penetrate through the heat dissipating fins 4 and are further transversely provided with positioning holes, the heat pipes and the heat dissipating fins 4 are fixedly connected at the joints of the positioning holes, the heat dissipating fins 4 can achieve certain supporting and fixing effects on the heat pipes through the positioning holes formed in the heat dissipating fins, meanwhile, the heat dissipating fins achieve a certain protection effect, and the heat pipes are prevented from being damaged and broken by external force.

As shown in Figures 2 and 4, the two ends af ths double-rpipe heat exchanger 1 are connected through the support 6, fixing holes are formed in the upper and lower faces of the support 6, and the two ends of the double-~ pipe heat exchanger 1 penetrate through the {fixing holes to be fixed.

A circle of housing 5 is arranged on the outer sides of the double-pipe heat exchangers 1 and the row type heal pipes 2, the housing 5 is fixed through supports 6 on the two sides, the housing is reticular, the housing achieves a protection effect on the heat pipes and also prevents the human body or other animals from being scalded as the human body or small animals directly suffer from high temperature at the positions of the heat pipes, and meanwhile temperature sources can be dissipated through the reticular structure.

Claims (10)

Conclusions 1. A temperature-conducting apparatus composed of rows of heat pipes is characterized by: double-pipe heat exchangers including the upper double-pipe heat exchanger and the lower double-pipe heat exchanger, wherein the two ends of the double-pipe heat exchangers are provided with connection parts (the connection parts are used for connecting pipes for passage of a temperature transfer medium); also rows of heat pipes connected to the upper twin-pipe heat exchanger and the lower twin-pipe heat exchanger, the rows of heat pipes comprising a plurality of heat pipes arranged at intervals in the axial directions of the twin-pipe heat exchangers. The two ends of each heat pipe make contact with the upper twin-pipe heat exchanger and the lower double-pipe heat exchanger; on the temperature transfer medium conducts the temperature to the rows of heat pipes through the double pipe heat exchangers and then the temperature is dispersed to the outside. The temperature conducting device composed of rows of heat pipes according to claim 1, characterized in that : the die pipe heat exchangers are tubular heat pipes and passages for conveying the temperature transfer medium are formed in the pipes. The temperature-conducting apparatus, composed of rows of heat pipes, according to claim 2, characterized in that : each twin-pipe heat exchanger comprises a ion pipe and a hump pipe, the inner pipe and the outer pipe being arranged concentrically. The outer pipe is a tubular heat pipe, the inner pipe is encased in the outer pipe. and the outer wall of the inner pipe is firmly attached to the inner wall of the outer pipe. The temperature-conducting device composed of rows of heat pipes according to claim 3, characterized in that : the rows of heat pipes penetrate through the inner walls of the double-pipe heat exchangers and then extend into the double-pipe heat exchangers so that the temperature transfer medium of the double-pipe heat exchangers enters directly makes contact with one end of the heat pipes, The temperature control device composed of rows of heat pipes according to claim 3, characterized in that : the rows of heat pipes are flat heat pipes and are connected to the flat side. with the side of the outer walls of the twin-pipe heat exchangers in a bonded manner, The temperature conducting device composed of rows of heat pipes according to claims 1-5, characterized in that : a phase change working medium is injected in a sealed manner into the vacuum sealed heat pipes, and grooves or capillary cores are provided in the heat pipes. The temperature conducting device made up of rows of heat pipes according to claim 6, characterized in that : a plurality of 16 pairs of heat emitting fins are arranged vertically to the rows of heat pipes, intersticing the rows of heat pipes. The multiple pairs of fins are evenly spaced. The temperature-conducting device, composed of rows of heat pipes, according to claim 7, is characterized in that : the heat-releasing fins are provided transversely with a plurality of positioning holes. The heat pipes penetrate through the positioning holes and the outer walls of the heat pipes contact the heat-releasing fins at the joints of the positioning holes. The temperature-controlling device, composed of rows of heat pipes, according to claims 1-5, 7 and 8, is characterized in that : the two ends of the double-pipe heat exchangers are connected by supports, fixing holes are formed in the upper and lower surfaces of the supports, and the two ends of the double-plip heat exchangers penetrate through the fixing holes to be fixed. The temperature conducting device made up of rows of heat pipes according to claim 9, characterized in that : an enclosing housing is arranged on the outer sides. of the double-pipe heat exchangers and the rows of heat pipes, The housing is fixed by means of the supports on the two sides, The housing is reticulated.